Method for manufacturing casing from a continuous tube



F. ZIOLKO Aug. 27, 1968 METHOD FOR MANUFACTURING CASING FROM A CONTINUOUS TUBE l5 Sheets-Sheet 1 Original Filed May 29, 1963 v INVENTOR.

FAAA/c/J c/ Zoz/ro F. ZIOLKO Aug. 27, 1968 METHOD FOR MANUFACTURING CASING FROM A CONTINUOUS TUBE l5 Sheets-Sheet 2 Original Filed May 29, 1963 INVENTOR. f/F/l/vc/j 1 Z/04 K0 F. ZIOLKO Aug. 27, 1968 METHOD FOR MANUFACTURING CASING FROM A CONTINUOUS TUBE Original Filed May 29, 1963 15 Sheets-Sheet 5 INVENTOR. fk/m c/s Z /04 K0 ATTdR/VE) 1 3% %m m aw p Q 3% w www 3 w QM \R km mm wax Aug. 27, 1968 F. ZlOLKO 3,399,066

METHOD FOR MANUFACTURING CASING FROM A CONTINUOUS TUBE Original Filed May 29, 1963 15 Sheets-Sheet 4.

I N VEN TOR. fPA/vc/s Z /0LA 0 MAJ.

F. ZIOLKO METHOD FOR MANUFACTURING CASING FROM A CONTINUOUS TUBE l5 Sheets-Sheet 5 Original Filed May 29, 1963 INVENTOR.

9 fPAr/vc/r d Z/OA/(O /5 g M AW ATTORNEY Aug. 27, 1968 F. ZIOLKO 3,39

METHOD FOR MANUFACTURING CASING FROM A CONTINUOUS TUBE Original Filed May 29, 1963 15 Sheets-Sheet 6 I INVENTOR. 232 x4 4 755 /5 nPA/w/sdZa/a F. ZIOLKO Aug. 27, 1968 METHOD FOR MANUFACTURING CASING FROM A CONTINUOU-i TUBE Original Filed May 29, 1963 15 Sheets-Sheet '7 mNUi xv \i INVENTOR. /:FA/V'/5 2704 K0 ATTORNEY F. ZIOLKO Aug. 27, 1968 METHOD FOR MANUFACTURING CASING FROM A CONTINUOUS TUBE l5 Sheets-Sheet 8 Original Filed May 29, 1963 INVENTOR.

fPA/vc/s 1 Z/a4/(0 gang ATTOENEY Aug. 27, 1968 F. ZIOLKO 3,399,055

METHOD FOR MANUFACTURING CASING FROM A CONTINUOUS TUBE Original Filed May 29, 1963 15 Sheets-Sheet 9 BY MAW ATTORNEY Aug. 27, 1968 F. ZIOLKO 3,399,065

METHOD FOR MANUFACTURING CASING FROM A CONTINUOUS TUBE Original Filed May 29, 1963 15 Sheets-Sheet 10 I N VEN TOR. [QM/V475 n/. Z /0 4 K0 y/jwulw ,4 TTOENEY Aug. 27, 1968 F. ZIOLKO 3,399,066

METHOD FOR MANUFACTURING CASING FROM A CONTINUOUS TUBE 15 Sheets-Sheet l1 &F- Tlqa 12 Original Filed May 29, 1963 32 'TlqiiH.

INVENTOR. f F/l/VC/f dZOL/(O BY m w Aug. 27', 1968 F. ZIOLKO 3,399,05$

METHOD FOR MANUFACTURING CASING FROM A CONTINUOUS TUBE Original Filed May 29, 1963 15 Sheets-Sheet 12 Q lax. M0210 fd b/ibna/j IN VEN TOR.

F. ZIOLKO Aug. 27, 1968 METHOD FOR MANUFACTURING CASING FROM A CONTINUOUS TUBE l5 Sheets-Sheet 14.

Original Filed May 29, 1963 ATTORNEY F. ZIOLKO Aug. 2'7, 1968 METHOD FOR MANUFACTURING CASING FROM A CONTINUOUS TUBE 15 Sheets-Sheet 15 Original Filed May 29, 1963 INVENTOR. 1 fiem c/f 1 Z04 K0 A TTOK/VE Y United States Patent 3,399,066 METHOD FOR MANUFACTURING CASING FROM A CONTINUOUS TUBE Francis Ziolko, Somerville, N.J., assignor to Johnson & Johnson, a corporation of New Jersey Original application May 29, 1963, Ser. No. 284,048, now

Patent No. 3,315,300, dated Apr. 25, 1967. Divided and this application Dec. 1, 1966, Ser. No. 600,690

3 Claims. (Cl. 99-176) ABSTRACT OF THE DISCLOSURE A continuous, inflated collagen tube is shirred on a mandrel disposed axially within the tube by the Wiping action of flexible fingers mounted on a pair of coacting, shirring rolls. The diameter of the inflated tube prior to shirring is continuously monitored by contacting the surface of the inflated tube with a dancer roller to provide a signal that is indicative of the diameter of the tube. The shirred tube is cut into discrete lengths, compressed, and delivered to a discharge station where certain links, the diameter of which varies from predetermined limits, is segregated in response to the signal.

This application is a division of my copending application Ser. No. 284,048, filed May 29, 1963; now Patent No. 3,315,300, issued Apr. 25, 1967.

The present invention relates to the manufacture of casings from a continuous, inflated tube and, more particularly, to a new and improved method for producing shirred and compressed lengths from a continuous tube of extruded and dried collagen.

The process of the invention is adapted to be used in the production of edible casings for fresh pork sausage, and sausages of the Wiener or frankfurter types, the casings being readily edible along with the meat product with which it is stuffed.

Natural casings produced from the intestines of animals, such as sheep, hogs, and cattle, have a number of faults. They are extremely high in bacteria count and, thus, difficult to properly prepare for human consumption. Natural casings fluctuate in availability, price, size, and edibility. Except for some casings derived from sheep, such casings are tough and hard to masticate.

Because of these shortcomings, a number of attempts have been made to produce edible, synthetic casings from protein sources, such as, collagen. A solution to the problem of producing edible, synthetic sausage casings from collagen is shown and described in US. Patent No. 3,123,653, granted on Mar. 3, 1964. It has been discovered that an exceedingly thin-walled tube of collagen casing material may be produced from a fluid mass of swollen collagen fibrils having a collagen solids content of the order of at least 2.5 percent, and less than 6 percent, which is much lower than heretofore used in the numerous unsuccessful attempts to produce edible, synthetic casings.

The collagen mass is extruded in the form of a continuous collagen tube, preferably by means of an extruder embodying a pair of oppositely-rotating discs, as shown and described in US. Patent No. 3,122,788. The extruded collagen tube is then subjected to a plurality of postextrusion treatments, including inflating and air-drying to produce a continuous, thin-Walled tube of dried collagen, forming sausage casings which are tender and readily cookable and edible. Throughout the entire processing of the extruded collagen tube, great care must exercised because of the exceedingly fragible and delicate nature of the tubing material. Starting with a solids content of about 4 percent in its freshly extruded form in "ice sion of a novel and improved method for shirring the leading end of said continuous, thin-walled tube of dried collagen, severing the shirred portion thereof into predetermined lengths, and compressing the shirred lengths to form compact, shirred units, and depositing the compressed units into a delivery chute for packaging and heat curing. The shirred, compressed and cured casing lengths can be easily handled and transported, and are ready at any time, without further preparation, to be applied to a stufiing device for filling with sausage emulsion. By way of contrast, heretofore, only non-collagenous synthetic casings; such as, cellulose casings, were available in shirred form.

GENERAL DESCRIPTION In the manufacture of the synthetic collagen casing with which the present invention is used, the continuous, tubular body of collagen is travelled through a drying chamber in which it is dried to a thin, tubular form by maintaining the length thereof in the chamber inflated to a selected diameter with controlled air pressure, and directing jets of warm, dry air against the exterior thereof as the collagen tube moves through the drier.

Air for inflating the collagen body during its travel through the drying chamber is provided from a hollow shirring mandrel axially disposed within the tubing and onto which the leading end of the dried, inflated collagen body is advanced by a pair of opposed feed rolls, which also serve to pull the tubing through the drier.

The leading end of the dried collagen tube advanced along the shirring mandrel by the feed rolls is engaged by a pair of opposed shirring rolls which pleat or shirr the tubing. The rolls are provided with flexible extensions or fingers of resilient material, such as, rubber, and are formed with relatively long radius of bending to apply a gentle wiping action to the collagen tube.

When a pre-selected length of tubing has been shirred, a cutter device is actuated to sever the shirred section from the leading end of the collagen tube. After the severing operation, the shirring rolls are pivoted away from position adjacent the shirring mandrel to permit entry therebetween of a reciprocating transfer and compression member. This transfer and compression member engages the trailing end of the severed, shirred section and moves it axially along the shirring mandrel away from the shirring zone and against a yieldable abutment adjacent the end of the shirring mandrel remote from the shirring rolls. The transfer and compression member applies an axial force to the shirred section by compressing it against the abutment, thereby reducing the length of the section. The compressive force on the shirred section is maintained while the shirring rolls resume shirring the next section from the leading end of the tube.

Before the conclusion of the next shirring operation, the transfer and compression member releases the cornpressed, shirred section and returns to position adjacent the shirring rolls to await the next successive shirred section. Substantailly simultaneously with the release of the compressed, shirred section, an ejector member is actuated to engage the compressed, shirred section and strip it from the shirring mandrel into a receiving member.

It is additionally necessary to ensure that the finished shirred casing sections are of collagen tubing having a generally uniform internal diameter, which is the internal diameter of the tubing as extruded and so maintained throughout the wet treatment thereof. There is provided means in the drying chamber itself for controlling the internal, inflating pressure of the air issuing from the shirring mandrel to maintain the internal diameter of the collagen tubing substantially constant during the drying thereof. By so maintaining the diameter of the tubing as it is dried, deleterious stretching or shrinking of the collagen tubing is avoided and a collagen casing is produced having the desired diameter. It has been found that a casing produced from a collagen tube that has been unduly stretched or expanded exhiblits a loss of elasticity, adversely affecting the casings ability to withstand the stresses or stuffing and linking. A casing from a collagen tube of sub-standard diameter will not yield the proper size sausage when stuffed.

As part of the present invention, there is also provided metering means which likewise assist in ensuring that the finished, shirred casings are of proper diameter, by causing out-sized casing lengths to be sensed and discarded. The metering means of the present invention is located adjacent to the entry of the tubing into the bite of the feed rolls. The collagen tubing is disposed for travel between a pair of relatively-movable rollers, the lower roller being fixed in position while the upper roller, a dancer roller, is mounted for vertical movement following the tubing contour. The dancer roller is adapted to vary a control signal when raised or lowered beyond the selected tubing diameter value.

When the dancer roller senses that a portion of the dried tubing has a greater or smaller inflated diameter than the required inflated casing diameter, the signal variation therefrom energizes a time-delay relay. The time delay relay is adapted, in turn, to actuate a reject member when a selected amount of the tubing diameter is above or below standard. When the shirred length which includes the portion of the collagen tubing of improper diameter is ejected from the shirring apparatus, as described heretofore, such shirred length, rather than being delivered into the receiving member with shirred casings of proper diameter, is delivered by means of the reject member to a reject tray with other casings of improper diameter. Thus, all the shirred casing lengths formed of a collagen tubing having substantially the same desired uniform diameter are separated and segregated from those of improper diameter.

Occasionally, as the inflated collagen tube travels through the drying chamber, it becomes rotated about its central axis and circumferentially twisted. A twisted tubing presents problems in the subsequent shirring and compacting operations, and produces a finished casing length having an unsightly appearance. It may also happen that the tubing becomes so twisted that the inflated tube becomes pinched, interrupting the air flow in the tubing.

To correct any twist that may develop in the dried collagen tubing as it enters the shirring mechanism, there is provided a novel detwister unit which is constructed and arranged to impart to the twisted tubing a twist in the opposite direction, thus, in effect countering the tubing twist and straightening the inflated tubing prior to its engagement by the feed rolls. This novel twister unit includes a pair of vertically-disposed rollers frictionally engaging opposite sides of the inflated collagen tube moving therebetween. One of the rollers is adapted for pivotal movement, and can be pivoted toward or away from the shirring apparatus. By suitably pivoting this movable roller out of co-planar relationship with its coacting roller, a twist can be imparted to the tubing moving between the rollers in a direction opposite to the direction of twist in the tubing. The twist thus effected by the twister unit counteracts the twist in the tubing and properly orients the tubing as it enters between the feed rolls.

The apparatus is simpler and less expensive to construct and maintain than comparable shirring devices heretofore available. In addition, the present invention produces a shirred and compressed casing length having generally more uniform size, appearance, and compactness than previously realized, thereby being easier to handle during stufling. Further, the structure and operation of the invention lends itself easily to mass production techniques and requirements.

OBJECTS It is, therefore, an object of the present invention to provide a novle, improved and closely-controlled method for producing shirred, compacted lengths of collagen cas ing from a continuous, inflated tube of dried collagen.

It is also an object of the invention to provide a novel and improved method for producing predetermined lengths of shirred, compacted collagen casing from the leading end of a continuous, inflated tube of dried collagen, engaging successive shirred and severed casing lengths and moving them to a compression station where an axial compressive force is applied on the shirred casings to reduce their length.

An additional object of the invention is to provide a new method for shirring a continuous, inflated dried collagen tube into compact, shirred casings of a preselected length, transferring successive shirred and severed casings lengths to a compression station Where an axial compressive force is applied to the shirred casings to reduce the length thereof, and moving the compressed, shirred casings into a receiving memebr.

Another object of the invention is to provide a new and improved method for continuously monitoring the dried tubing diameter as it enters the shirring mechanism, and rejecting any shirred casing length formed of collagen tubing having an internal diameter beyond pre-selected upper or lower limits.

A further object of the invention is to provide a novel method for rotating an inflated, twisted collagen tubing in a direction opposite to the direction of tubing twist, thereby counteracting the tubing twist and straightening the collagen tubing for subsequent shirring, severing, and compressing into shirred collagen casing lengths.

Objects and advantages of the invention will be obvious herefrom, or may be learned by practice with the invention, the same being realized and attained by means of the instrumentalities and combinations pointed out in the appended claims.

The foregoing general description and the following detailed description are exemplary and explanatory, but are not restrictive of the invention.

Of the drawings illustrating, by way of example, a preferred embodiment of the invention:

FIGURE 1 is a perspective view, partly schematic, of a device embodying the present invention.

FIGURE 2 is a perspective view of the metering device and detwister unit of the present invention.

FIGURE 3 is a plan view of the mechanism shown in FIGURE 1.

FIGURE 4 is a side elevation of the embodiment of the mechanism shown in FIGURE 3.

FIGURE 5 is a front view, partly broken away, of the mechanism shown in FIGURE 4.

FIGURE 6 is a side elevation of the feed and shirring roll drive mechanism shown on the opposite side from that shown in FIGURE 4.

FIGURE 7 is a sectional view taken along line 77, FIGURE 6, showing the shirring rolls inoperative, closed, shirring position.

FIGURE 8 is a sectional view similar to FIGURE 7,

but illustrating the shirring rolls in nonoperative, open position.

FIGURE 9 is a sectional view taken along line 9-9, FIGURE 6.

FIGURE 10 is a detailed side elevation of the'shirring mandrel rear support members and associated elements. FIGURE 11 is a front view of the mechanism shown in FIGURE 10.

FIGURE 12 is a cross-sectional, side view of the shirring mandrel rear support members, shown in closed, operative mandrel support position.

FIGURE 13 is a side elevation, partly in section, of the mandrel rear support members, shown in open, nonoperative position.

FIGURE 14 is a detailed view, partly in section, of the mandrel front support members, shown in mandrel support position.

FIGURE 15 is a sectional view taken along lines 1515, FIGURE 12.

FIGURE 16 is a side elevation of the shirring mandrel with the feed rolls and shirring rolls shown partly in section, and the front and rear mandrel support members shown in phantom.

FIGURE 17 is a sectional view taken along lines 1717, FIGURE 16.

FIGURE 18 is a longitudinal, sectional view of the mandrel end piece.

FIGURE 19 is a sectional view taken along lines 19-49, FIGURE 16.

FIGURE 20 is a plan view of the portion of the shirring mandrel disposed between the shirring rolls.

FIGURE 21 is a perspective view of the shirring mandrel casing hold-off clip.

FIGURE 22 is a front view of the casing-receiving and depositing mechanism.

FIGURE 23 is a side elevation of the mechanism shown in FIGURE 22.

FIGURE 24 is a front view of the mechanism shown in FIGURE 22, illustrating the mechanism in casing-deposit position.

FIGURE 25 is a plan veiw of a portion of the transfer and compressor member, illustrating the tubing gripper element thereof and its associated structure.

FIGURE 26 is a perspective view of a modified form of casing-receiving and depositing mechanism.

FIGURE 27 is an enlarged, lengthwise, cross-sectional view of the mechanism shown in FIGURE 26.

FIGURES 28A-28I illustrate schematically the successive operations performed by the invention.

FIGURE 29 is a schematic diagram of a suitable pneumatic control system for the invention.

FIGURE 30 is a schematic wiring diagram of a suitable electrical control system for the invention.

FIGURE 31 is a timing diagram of a typical cycle of operation of the invention.

FIGURE 32 is a perspective view of a modified form of the invention as adapted to a production line, wherein the mechanism of the invention is shown mounted horizontally rather than on the vertical support of FIGURE 2, and with two adjacent side-by-side units.

Referring now to the drawings wherein there is illustrated the preferred form of the invention, FIGURE 1 illustrates somewhat diagrammatically the structure of the present invention, while FIGURES 28A28I illustrate schematically the cyclic shirring operation performed by the mechanism of the invention.

The tubular body C, produced and processed as described in US. Patent Nos. 3,123,653 and 3,122,788, is travelled through a suitable drying chamber (not shown) and a rehumidification chamber R (see FIGURE 2). Having now acquired its final dimensions, body C is disposed about an axially-disposed hollow shirring mandrel 10, which forces pressurized air into body C for inflating it as it passes through the drier and rehumidification chamber R and onto mandrel 10.

To assist in feeding the dried body C along shirring mandrel 10, there is provided a pair of feed rolls 12 and 14 mounted, respectively, above and below shirring mandrel 10. Rolls 12 and 14 are provided with resilient coverings 15 of silicone rubber or similar resilient material which embrace the tubing C from above and below, compressing it against the exterior surface of shirring mandrel 10. In addition, rolls 12 and 14 draw body C through the drying chamber and feed the leading end thereof along shirring mandrel 10 to a pair of co-acting shirring rolls .16 and 18, which form pleats or folds in the leading end thereof. Rolls 12 and 14 are so constructed and disposed that a small amount of air leaks past rolls 12 and 14 to maintain inflated the portion of tubing C between feed rolls 12 and 14 and shirring rolls l6 and 18. (See FIGURE 1.) This section of tubing C is kept inflated to facilitate the shirring operation.

Rolls 16 and 18, are preferably provided with shirring members disposed angularly to the roller axes like those disclosed in Mayer Patent No. 1,302,194, being provided with a plurality of helically-disposed peripheral fingers or wipers .19 which frictionally engage opposed portions of the outer surface of tubing C. Unlike said Mayer patent, however, fingers 19 are formed of very flexible material, such as, sponge rubber, and are constructed with a relatively, long radius of bending so as to apply a gentle, prolonged wiping action progressively to the thin, fragile, and delicate collagen tube C engaged thereby.

Referring specifically to FIGURES 28A-28I, which disclose sequentially the operations of the mechanism of the present invention, when a pre-determined length of tubing has been shirred onto mandrel 10 by rolls 16 and 18, a pair of opposed cutters 20 and 22 are actuated, as described hereinafter in detail, and travel toward mandrel 10 and into engagement with the tubing C immediately before it passes between shirring rolls 16 and 18. These cutters 20 and 22 sever the shirred section S at the leading end of tubing C from the remainder thereof.

As the cutters 20 and 22 are withdrawn from operative severing position adjacent mandrel 10, a transfer and compressor member, designated generally 24, is energized and moved laterally toward and against mandrel 10 in an exposed section 11 thereof between feed rolls 12 and 14 and shirring rolls .16 and 18, between the trailing end of shirred section S and the leading end of tubing C (see FIGURE 1 and 28B).

The transfer and compressor member 24 is then travelled in the direction of arrow Z, FIGURE 28C, to move shirred section S away from the shirring rolls 16 and 18 and axially compress it at a compression station on mandrel 10 against a yieldable barrier 26 temporarily positioned in the path of travel of section S along mandrel 10.

To permit passage of member 24 therepast, shirring rolls 16 and 18 are moved away from mandrel 10 and out of contact therewith during the transfer of section S along mandrel 10 to barrier 26.

To assist in supporting mandrel 10 during the period that shirring rolls 16 and 18 are out of operative shirring position, there is provided a pair of opposed, front gripper units 28 and 30 which are disposed between shirring rolls .16 and 18 and barrier 26. Gripper units 28 and 30 are actuated and moved into gripping engagement with an exposed section 13 of mandrel 10 as transfer member 24 moves therepast toward barrier 26.

Gripper units 28 and 30 remain in gripping engagement with mandrel 10 as shirring rolls 16 and 18 are returned to operative shirring position and start to shirr the next section S on the leading end of tube C. With shirring rolls 16 and 18 returned to shirring position, transfer and compressor member 24 is moved out of engagement with shirred section S to await the next shirring cycle.

As member 24 is moved away from mandrel 10 and section S, an ejector member 32 is actuated and moved into engagement with mandrel 10 between front grips 28 and 30 and the trailing end of shirred section S. With ejector 32 adjacent mandrel 10, the rear mandrel support grips 34 and 36, through which air to mandrel 10 is supplied, and by means of which mandrel 10 is normally supported, are moved away from mandrel 10 and out of gripping engagement therewith. This movement of grips 34 and 36 provides an unobstructed path for the ejection of shirred section S from the mandrel .10. However, front gripper units 28 and 30 are still in gripping engagement 7 with mandrel 10 and are supporting it while rear grips 34 and 36 are temporarily out of mandrel support position.

With its path cleared, ejector 32 is moved in the direction of arrow X, FIGURE 28E, to remove shirred section S from mandrel 10. At the end of the travel of ejector 32 in the direction of arrow X, and completion of the casing removal, rear gripper units 34 and 36 are returned to operative mandrel gripping engagement and front gripperunits 28 and are moved away from mandrel 10, clearing the path for the next successive shirred portion at the leading end of tubing C as it travels along mandrel 10.

Simultaneously with the de-actuation of front grips 28 and 30, transfer member 24 is travelled in the direction of arrow Y, FIGURE 28H, to return transfer member 24 to its original position to await transfer andcompression of the next shirred section S.

FEED AND SHIRRING ROLL SUPPORT AND DRIVE MECHANISMS 2 Referring now in detail to FIGURES 1-9 which illustrate one embodiment of the invention, referring to FIGURE 1 feed rolls 12 and 14 are mounted on the ends of shafts 38 and 40, respectively, both supported in suitable bean'ngs in mounting plate 42 carried by the main machine frame F. To rotate shaft 38, there is provided at its free end a sprocket 44, about which is trained an endless chain 48 for reasons hereinafter set forth.

To transmit rotation from shaft 38 to shaft 40, there r is also provided on shaft 38 a gear element 50 which is in meshing engagement with a similarly constructed gear element 52 fixed to shaft 40. 7

The end of shaft 40 remote from feed roll 14 has mounted thereon a double-tract sprocket 54, about one track of which is trained an endless drive chain 56. Chain 56 also passes around a sprocket 58 fixed to one end of transmission shaft 60. The other end of shaft 60 is pro- 1 vided with a sprocket 62 with an endless chain 64 trained there-around. Chain 64 also passes around sprocket 66 fixed to the output shaft 68 of a suitable power source, such as, a gear reduction motor 70, which is energized by an operator at the start of the machine operations.

In operation, gear 52, coupled in driven relationship with motor 70, effects equal but opposite rotation of its meshing gear 50 and, as shaft 40 is rotated by motor 70, shaft 38 is also rotated thereby but in an opposite direction, rotating rolls 12 and 14 in the respective directions indicated by the arrows in FIGURE 1. Thus, rolls 12 and 14, rotating in opposite directions, effect travel of tubular body C along mandrel 10.

Shirring rolls 16 and 18 are, in turn, mounted on the ends of shafts 72 and 74 respectively. Shirring rolls 16 and 18 are preferably driven in synchronism with rolls 12 and 14. To accomplish this, a sprocket 76 is fixed to shaft 72 and endless chain 48 trained therearound. Since chain 48 also passes around sprocket 44 on shaft 38, rotation of shaft 38, in turn, rotates shaft 72 also and in the same direction as shaft 38.

In like manner, shaft 74 is provided at the end thereof remote from roll 18 with a sprocket about which is trained an endless chain 77. Chain 77 also passes around the other track of sprocket 54 thus coupling shafts 40 and 74 for rotation in the same direction.

To provide for the movement of shirring rolls 16 and 18 toward and away from mandrel 10, shafts 72 and 74 (see FIGURES 7 and 8) are each eccentrically mounted and rotatably supported in outer sleeve members 78 and 80 respectively. Sleeves 78 and 80 are rotatably mounted in suitable accommodating openings 82 and 84 respectively in plate 42, and are each additionally supported in suitable bearings 86 and 88 fixed to plate 42.

Sleeves 78 and 80 are, in turn, provided at the ends thereof remote from rolls 16 and 18 with meshing gear members 90 and 92 respectively (see FIGURE 6) each of which is similar in construction and fixed to and rotatable with its associated sleeve. To effect rotation of gears 90 and 92 and thus their associated sleeves 78 and 80, gear 90 is also in meshing engagement with a gear sector 94 rotatably supported on a stub shaft 96 carried by plate 42. Gear sector 94, in turn, is pinned to the free end of cylinder rod 98 of a suitable pneumatic cylinder 100 secured to plate 42.

When, during the cyclic operation of the machine, cylinder 100 is actuated, as hereinafter described, cylinder rod 98 thereof is extended rotating gear sector 94 in the direction indicated by the arrow thereon in FIGURE 6.

Since gear sector 94 and gear 90 and gears 90 and 92 are in meshing engagment, this rotation of sector 94 in turn effects rotation of gears 90 and 92 in the-directions respectively indicated by the arrows thereon in FIG- URE 6. This rotation of gears 90 and 92 in turn rotates sleeves 78 and 80 fixed thereto in like direction. However, since shafts 72 and 74 are eccentrically supported in sleeves 78 and 80, rotation of the sleeves 78 and 80 in such directions, effects movement of shafts 72 and 74 away from each other and thus, moves shirring rolls 16 and 18 apart and out of operative shirring position adjacent mandrel 10 as shown in FIGURE 8.

When during the shirring cycle shirring rolls 16 and 18 are to be returned to operative shirring position, cylinder 100 is deenergized retracting its rod 98 and thus reversing the direction of rotation of sector 94, gears 90 and 92, and sleeves 78 and 80 described heretofore, thereby returning shirring rolls 16 and 18 to operative shirring position shown in FIGURES l and 7.

Sprockets 44 and 54 are similar in diameter and construction, as are gear elements 50 and 52, .so that feed rolls 12 and 14 rotate at the same speed continuously as long as motor 70 is energized, while shirring rolls 16 and 18 likewise rotate at the same speed continuously as long as motor 70 is energized, since sprockets 75 and 76 are similar in diameter and construction. Further, it has been found desirable to maintain a degree of tension on the tubing C in the portion thereof between the feed rolls 12 and 14 and the shirring rolls 16 and 18. To provide this tension, sprocket 76 is of a smaller diameter than its associated sprocket 44, while sprocket 75 is of a smaller diameter than its associated sprocket 54.

Preferably, the diameters of sprockets 44 and 54 are about 50 percent larger than the diameters of sprockets 76 and 75. Thus, every revolution of sprockets 44 and 54 effects 1% revolutions of sprockets 76 and 75. For every revolution of feed rolls 12 and 14, shirring rolls 16 and 18 complete 1% revolutions. Therefore, tubing C is being shirred faster than it is being fed and, accordingly, a controlled degree of tension or stretch is applied to the tubing section between feed rolls 12 and 14 and shirring rolls 16 and 18. It will be understood that the degree of tension applied can be readily altered to any desired amount by changing the relative gear ratios of sprockets 44, 54, 75, and 76.

To furnish the desired tension on chains 48 and 77, there are provided tension sprockets 102 and 104, one for each chain. Sprockets 102 and 104 (see FIGURE 6) each rotatably secured to an associated lever arm 106 and 108 pivotally mounted on plate 42 and biased by an associated spring 110 and 112 to urge sprockets 102 and 104 into normal, resilient engagement with their associated chains.

In like manner, means are also provided for adjusting the operative position of rolls 16 and 18 (see FIGURES 6, 7, and 8). Said means include an elongated adjusting member 114 threaded for travel through a support block 116 on plate 42 adjacent sector 94. One end 115 of member 114 bears against sector 94 as shown in FIGURE 6. The other end of member 114 is provided with an actuating' head 117 such that, when head 117 is suitably rotated, member 114 is travelled through block 116 to urge end 115 thereof against sector 94 thus pivoting sector 94 about shaft 96. This, in turn, rotates gears 90 and 92 and sleeves 78 and 80 to suitably locate rolls 16 and 18 in proper adjusted operative shirring position.

MANDREL CONSTRUCTION Turning to FIGURES 16-21, there is illustrated the preferred form of mandrel which is formed in two separate matching sections 118 and 120. Section 118 comprises an inner metallic sleeve 122 with a smooth outer covering 124, while section 120 includes an inner metallic sleeve 126 with a fluted or longitudinally-ribbed outer covering 128. Preferably, section 120 is of slightly smaller outer diameter than section 118. This coupled with the fluting of covering 128 results in a substantial reduction in frictional drag of the shirred casing travelled along section 120. It will be understood that the pleated casing section S exhibits greater resistance to travel along mandrel 10 than does the inflated, unpleated tubing C. Thus, mandrel 10 includes the fluted section 120 in that portion thereof past the shirring area and over which shirred section S travels. However, to minimize frictional resistance, over the entire mandrel length, coverings 124 and 128 are both of material having a low coefiicient of friction, such as, one of the tetrafluoroethylene resins.

The leading end 119 of first section 118 is preferably tapered to facilitate insertion into tubular body C. First section 118 is coupled to second section 120, adjacent the location of shirring rolls 16 and 18, by means of a hollow, metallic coupling 130 threaded at each end thereof to accommodate cooperating threaded sections 132 and 134 on sleeves 122 and 126 respectively.

The end of section 120 remote from rolls 16 and 18 and adjacent rear grip blocks 34 and 38 is secured to an air inlet section 136 which is preferably of metal closed at the end thereof remote from section 120 (FIGURES l6 and 18). Air inlet section 136 is provided with an internal bore 138 which communicates adjacent the closed end with a transverse air inlet port 140. Port 140 is adapted to cooperate with an air inlet bore 156 in rear grip 36 to normally admit air under pressure into the hollow interiors of sections 118 and 120 of mandrel 10 (FIGURES 12 and 13). For reasons explained in more detail hereinafter, the top surface 137 of section 136 is flat rather than rounded to facilitate gripping by block 34.

Mandrel 10 also includes adjacent the area of operation of front grips 28 and 30 an outer metal sleeve 142 attached as by silver soldering to inner metal sleeve 126 (see FIG- URES 16 and 17). The two sections 129 and 131 of outer, fluted, plastic sleeve 128 abut the front and rear edges of sleeve 142. Sleeve 142 also includes an annular groove 144 formed therein to accommodate the operative gripping portions of blocks 28 and 30.

It will be understood that mandrel 10 includes outer metallic sections 130, 136, and 142 adjacent the areas of operation along mandrel 10 of the shirring rolls 16 and 18, the rear grips 34 and 36 and the front grips 28 and 30 respectively to avoid the undue wear which the outer plastic covering would experience at such operative areas as a result of the intermittent frictional engagement of the mandrel 10 by these elements during the cyclic operation of the machine (see FIGURE 16).

It has been found desirable to keep tubing C centered on mandrel 10 as it is engaged by shirring rolls 16 and 18, thereby ensuring a uniform shirring operation. To assist in keeping tubing so centered, there is provided on mandrel 10 adjacent the entry of tubing C into the shirring zone, a casing alignment and tensioning member 146 seated on coupling 130 (FIGURES 16, 20, and 21). Member 146 includes an arcuate section 148 curved to conform to the upper contour of coupling 130 and is fixed to coupling 130 as by soldering to securely seat member 146 in position on mandrel 10. Member 146 also includes a pair of lateral extensions 150 and 152 of section 148 which are disposed on opposite sides of mandrel 10 when member 146 is seated thereon (see FIGURE 16). Sections 150 and 152 are preferably coplanar and are positioned in a common plane transverse to the plane of section 148.

In addition, the free ends 151 and 153 of sections and 152 respectively are divergent so that ends 151 and 153 are spaced from their associated sides of mandrel 10. In operation, as shown best in FIGURE 20, member 146 is seated on mandrel 10 inside tubular body C. The lateral extensions 150 and 152 have their free ends 151 and 153 in slight contact with opposite sections of the inner wall of tubing C as it moves therepast on its way to the shirring rolls 16 and 18. This arrangement thus keeps the side Walls of tubing C in spaced relationship relative to mandrel 10 and thereby centered thereon as the tubing C enters the shirring area.

In addition, member 146 provides a small degree of internal tension in tubing C just as it enters the bite of rolls 16 and 18 to eliminate any premature tubing wrinkles and thus assists in producing a uniformly, shirred section S.

MANDREL AIR SUPPLY Air under pressure is preferably introduced into tubing C at the start of the drying operation and tubing C is preferably maintained inflated during its travel through the drying chamber, rehu-midification chamber and during the shirring operation. In the preferred form of the invention, air is introduced into tubing C through the hollow interior of mandrel 10. To accommodate the passage of air therethrough mandrel 10, as described hereinabove (see FIGURES 17, 18, and 19), includes communicating sleeves 122 and 126 and air inlet bore 138. In turn, bore 138 cooperates with port 140 to admit air under pressure into the hollow interior of mandrel 10.

As shown best in FIGURES 12 and 13, port 140 forms an extension of cooperating port 154 when rear grips 34 and 36 are in operative mandrel gripping position. In turn, port 154 communicates with bore 156 in grip 36, in turn, suitably connected to air inlet line 158. To control the air pressure in line 158 and thus the air pressure emitted from mandrel 10, any suitable control means maybe used. It will be understood that when, during the cyclic operation of the machine, grips 34 and 36 are in operative gripping position as shown in FIGURE 12, air under pressure is normally fed through line 158, bore 156 and port 154 into and through port 140, bore 138 and sleeves 126 and 122, exiting from tapered front end 119 of mandrel 10 into the tubing C to inflate the tubing during the several steps described above.

During the machine cycle, grips 34 and 36 are moved away from mandrel 10 and out of operative position (see FIGURE 13). With grips 34 and 36 in open position, it may be desirable to provide an auxiliary air supply to maintain tubing C in inflated condition in the drier. To provide for this auxiliary air supply, an auxiliary air line port 160 and air line 162 are provided for temporarily directing pressurized air from a source of supply (not shown) toward and into port 140 and bore 138. It will be understood that grips 34 and 36 are out of operative gripping position for only a relatively short period during the shirring cycle, e.g., as the shirred section is ejected. Therefore, it is not always necessary to include an auxiliary air supply to keep tubing C inflated. However, port 160 and line 162 are provided in the event they may be necessary to continuously maintain the tubing in proper inflated condition (see FIGURE 12).

YIELDABLE BARRIER Referring to FIGURES 10 13, preferably yieldable barrier 26 and rear grip members 34 and 36 are constructed and operate as a unit. Barrier 26 includes a pair of spaced support rods 164 and 166 supported by grips 34 and 36 respective-1y. Rods 164 and 166 extend from their associated grip members 34 and 36 in a direction parallel to the longitudinal axis of mandrel 10 and toward shirring rolls 16 and 18. Slidably mounted on rod 164 is a casing stop block 168 while slidably mounted on rod 166 is a second cooperative casing stop block 170. Blocks 168 and 170 have cooperating adjacent faces or edges 

